office-gobmx/scaddins/source/analysis/analysis.cxx
2010-12-03 13:59:12 +00:00

1302 lines
33 KiB
C++

/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/*************************************************************************
*
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* Copyright 2000, 2010 Oracle and/or its affiliates.
*
* OpenOffice.org - a multi-platform office productivity suite
*
* This file is part of OpenOffice.org.
*
* OpenOffice.org is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License version 3
* only, as published by the Free Software Foundation.
*
* OpenOffice.org is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License version 3 for more details
* (a copy is included in the LICENSE file that accompanied this code).
*
* You should have received a copy of the GNU Lesser General Public License
* version 3 along with OpenOffice.org. If not, see
* <http://www.openoffice.org/license.html>
* for a copy of the LGPLv3 License.
*
************************************************************************/
#include "analysis.hxx"
#include <cppuhelper/factory.hxx>
#include <osl/diagnose.h>
#include <rtl/ustrbuf.hxx>
#include <rtl/math.hxx>
#include <sal/macros.h>
#include <string.h>
#include <tools/resmgr.hxx>
#include <tools/rcid.h>
#include "analysis.hrc"
#include "bessel.hxx"
#define ADDIN_SERVICE "com.sun.star.sheet.AddIn"
#define MY_SERVICE "com.sun.star.sheet.addin.Analysis"
#define MY_IMPLNAME "com.sun.star.sheet.addin.AnalysisImpl"
using namespace ::rtl;
using namespace ::com::sun::star;
//------------------------------------------------------------------
//
// entry points for service registration / instantiation
//
//------------------------------------------------------------------
extern "C" {
void SAL_CALL component_getImplementationEnvironment( const sal_Char** ppEnvTypeName, uno_Environment** /*ppEnv*/ )
{
*ppEnvTypeName = CPPU_CURRENT_LANGUAGE_BINDING_NAME;
}
sal_Bool SAL_CALL component_writeInfo( void* /*pServiceManager*/, registry::XRegistryKey* pRegistryKey )
{
if( pRegistryKey )
{
try
{
STRING aImpl = STRFROMASCII( "/" );
aImpl += AnalysisAddIn::getImplementationName_Static();
aImpl += STRFROMASCII( "/UNO/SERVICES" );
REF( registry::XRegistryKey ) xNewKey(
reinterpret_cast< registry::XRegistryKey* >( pRegistryKey )->createKey( aImpl ) );
SEQ( STRING ) aSequ = AnalysisAddIn::getSupportedServiceNames_Static();
const STRING* pArray = aSequ.getConstArray();
for( sal_Int32 i = 0 ; i < aSequ.getLength() ; i++ )
xNewKey->createKey( pArray[ i ] );
return sal_True;
}
catch( registry::InvalidRegistryException& )
{
OSL_ENSURE( sal_False, "### InvalidRegistryException!" );
}
}
return sal_False;
}
void* SAL_CALL component_getFactory( const sal_Char* pImplName, void* pServiceManager, void* /*pRegistryKey*/ )
{
void* pRet = 0;
if( pServiceManager && STRING::createFromAscii( pImplName ) == AnalysisAddIn::getImplementationName_Static() )
{
REF( lang::XSingleServiceFactory ) xFactory( cppu::createOneInstanceFactory(
reinterpret_cast< lang::XMultiServiceFactory* >( pServiceManager ),
AnalysisAddIn::getImplementationName_Static(),
AnalysisAddIn_CreateInstance,
AnalysisAddIn::getSupportedServiceNames_Static() ) );
if( xFactory.is() )
{
xFactory->acquire();
pRet = xFactory.get();
}
}
return pRet;
}
} // extern C
//------------------------------------------------------------------------
//
// "normal" service implementation
//
//------------------------------------------------------------------------
ResMgr& AnalysisAddIn::GetResMgr( void ) THROWDEF_RTE
{
if( !pResMgr )
{
InitData(); // try to get resource manager
if( !pResMgr )
THROW_RTE;
}
return *pResMgr;
}
STRING AnalysisAddIn::GetDisplFuncStr( sal_uInt16 nFuncNum ) THROWDEF_RTE
{
return String( AnalysisRscStrLoader( RID_ANALYSIS_FUNCTION_NAMES, nFuncNum, GetResMgr() ).GetString() );
}
class AnalysisResourcePublisher : public Resource
{
public:
AnalysisResourcePublisher( const AnalysisResId& rId ) : Resource( rId ) {}
BOOL IsAvailableRes( const ResId& rId ) const { return Resource::IsAvailableRes( rId ); }
void FreeResource() { Resource::FreeResource(); }
};
class AnalysisFuncRes : public Resource
{
public:
AnalysisFuncRes( ResId& rRes, ResMgr& rResMgr, sal_uInt16 nInd, STRING& rRet );
};
AnalysisFuncRes::AnalysisFuncRes( ResId& rRes, ResMgr& rResMgr, sal_uInt16 nInd, STRING& rRet ) : Resource( rRes )
{
rRet = String( AnalysisResId( nInd, rResMgr ) );
FreeResource();
}
STRING AnalysisAddIn::GetFuncDescrStr( sal_uInt16 nResId, sal_uInt16 nStrIndex ) THROWDEF_RTE
{
STRING aRet;
AnalysisResourcePublisher aResPubl( AnalysisResId( RID_ANALYSIS_FUNCTION_DESCRIPTIONS, GetResMgr() ) );
AnalysisResId aRes( nResId, GetResMgr() );
aRes.SetRT( RSC_RESOURCE );
if( aResPubl.IsAvailableRes( aRes ) )
{
AnalysisFuncRes aSubRes( aRes, GetResMgr(), nStrIndex, aRet );
}
aResPubl.FreeResource();
return aRet;
}
void AnalysisAddIn::InitData( void )
{
if( pResMgr )
delete pResMgr;
OString aModName( "analysis" );
pResMgr = ResMgr::CreateResMgr( ( const sal_Char* ) aModName,
aFuncLoc );
if( pFD )
delete pFD;
if( pResMgr )
pFD = new FuncDataList( *pResMgr );
else
pFD = NULL;
if( pDefLocales )
{
delete pDefLocales;
pDefLocales = NULL;
}
}
AnalysisAddIn::AnalysisAddIn( const uno::Reference< lang::XMultiServiceFactory >& xServiceFact ) :
pDefLocales( NULL ),
pFD( NULL ),
pFactDoubles( NULL ),
pCDL( NULL ),
pResMgr( NULL ),
aAnyConv( xServiceFact )
{
}
AnalysisAddIn::~AnalysisAddIn()
{
if( pFD )
delete pFD;
if( pFactDoubles )
delete[] pFactDoubles;
if( pCDL )
delete pCDL;
if( pDefLocales )
delete[] pDefLocales;
}
sal_Int32 AnalysisAddIn::getDateMode(
const uno::Reference< beans::XPropertySet >& xPropSet,
const uno::Any& rAny ) throw( uno::RuntimeException, lang::IllegalArgumentException )
{
sal_Int32 nMode = aAnyConv.getInt32( xPropSet, rAny, 0 );
if( (nMode < 0) || (nMode > 4) )
throw lang::IllegalArgumentException();
return nMode;
}
//-----------------------------------------------------------------------------
#define MAXFACTDOUBLE 300
double AnalysisAddIn::FactDouble( sal_Int32 nNum ) THROWDEF_RTE_IAE
{
if( nNum < 0 || nNum > MAXFACTDOUBLE )
THROW_IAE;
if( !pFactDoubles )
{
pFactDoubles = new double[ MAXFACTDOUBLE + 1 ];
pFactDoubles[ 0 ] = 1.0; // by default
double fOdd = 1.0;
double fEven = 2.0;
pFactDoubles[ 1 ] = fOdd;
pFactDoubles[ 2 ] = fEven;
sal_Bool bOdd = sal_True;
for( sal_uInt16 nCnt = 3 ; nCnt <= MAXFACTDOUBLE ; nCnt++ )
{
if( bOdd )
{
fOdd *= nCnt;
pFactDoubles[ nCnt ] = fOdd;
}
else
{
fEven *= nCnt;
pFactDoubles[ nCnt ] = fEven;
}
bOdd = !bOdd;
}
}
return pFactDoubles[ nNum ];
}
STRING AnalysisAddIn::getImplementationName_Static()
{
return STRFROMASCII( MY_IMPLNAME );
}
SEQ( STRING ) AnalysisAddIn::getSupportedServiceNames_Static()
{
SEQ( STRING ) aRet(2);
STRING* pArray = aRet.getArray();
pArray[0] = STRFROMASCII( ADDIN_SERVICE );
pArray[1] = STRFROMASCII( MY_SERVICE );
return aRet;
}
REF( uno::XInterface ) SAL_CALL AnalysisAddIn_CreateInstance(
const uno::Reference< lang::XMultiServiceFactory >& xServiceFact )
{
static uno::Reference< uno::XInterface > xInst = (cppu::OWeakObject*) new AnalysisAddIn( xServiceFact );
return xInst;
}
// XServiceName
STRING SAL_CALL AnalysisAddIn::getServiceName() THROWDEF_RTE
{
// name of specific AddIn service
return STRFROMASCII( MY_SERVICE );
}
// XServiceInfo
STRING SAL_CALL AnalysisAddIn::getImplementationName() THROWDEF_RTE
{
return getImplementationName_Static();
}
sal_Bool SAL_CALL AnalysisAddIn::supportsService( const STRING& aName ) THROWDEF_RTE
{
return aName.compareToAscii( ADDIN_SERVICE ) == 0 || aName.compareToAscii( MY_SERVICE ) == 0;
}
SEQ( STRING ) SAL_CALL AnalysisAddIn::getSupportedServiceNames() THROWDEF_RTE
{
return getSupportedServiceNames_Static();
}
// XLocalizable
void SAL_CALL AnalysisAddIn::setLocale( const lang::Locale& eLocale ) THROWDEF_RTE
{
aFuncLoc = eLocale;
InitData(); // change of locale invalidates resources!
}
lang::Locale SAL_CALL AnalysisAddIn::getLocale() THROWDEF_RTE
{
return aFuncLoc;
}
// XAddIn
STRING SAL_CALL AnalysisAddIn::getProgrammaticFuntionName( const STRING& ) THROWDEF_RTE
{
// not used by calc
// (but should be implemented for other uses of the AddIn service)
return STRING();
}
STRING SAL_CALL AnalysisAddIn::getDisplayFunctionName( const STRING& aProgrammaticName ) THROWDEF_RTE
{
STRING aRet;
const FuncData* p = pFD->Get( aProgrammaticName );
if( p )
{
aRet = GetDisplFuncStr( p->GetUINameID() );
if( p->IsDouble() )
aRet += STRFROMANSI( "_ADD" );
}
else
{
aRet = STRFROMANSI( "UNKNOWNFUNC_" );
aRet += aProgrammaticName;
}
return aRet;
}
STRING SAL_CALL AnalysisAddIn::getFunctionDescription( const STRING& aProgrammaticName ) THROWDEF_RTE
{
STRING aRet;
const FuncData* p = pFD->Get( aProgrammaticName );
if( p )
aRet = GetFuncDescrStr( p->GetDescrID(), 1 );
return aRet;
}
STRING SAL_CALL AnalysisAddIn::getDisplayArgumentName( const STRING& aName, sal_Int32 nArg ) THROWDEF_RTE
{
STRING aRet;
const FuncData* p = pFD->Get( aName );
if( p && nArg <= 0xFFFF )
{
sal_uInt16 nStr = p->GetStrIndex( sal_uInt16( nArg ) );
if( nStr )
aRet = GetFuncDescrStr( p->GetDescrID(), nStr );
else
aRet = STRFROMANSI( "internal" );
}
return aRet;
}
STRING SAL_CALL AnalysisAddIn::getArgumentDescription( const STRING& aName, sal_Int32 nArg ) THROWDEF_RTE
{
STRING aRet;
const FuncData* p = pFD->Get( aName );
if( p && nArg <= 0xFFFF )
{
sal_uInt16 nStr = p->GetStrIndex( sal_uInt16( nArg ) );
if( nStr )
aRet = GetFuncDescrStr( p->GetDescrID(), nStr + 1 );
else
aRet = STRFROMANSI( "for internal use only" );
}
return aRet;
}
static const char* pDefCatName = "Add-In";
STRING SAL_CALL AnalysisAddIn::getProgrammaticCategoryName( const STRING& aName ) THROWDEF_RTE
{
// return non-translated strings
// return STRFROMASCII( "Add-In" );
const FuncData* p = pFD->Get( aName );
STRING aRet;
if( p )
{
const sal_Char* pStr;
switch( p->GetCategory() )
{
case FDCat_DateTime: pStr = "Date&Time"; break;
case FDCat_Finance: pStr = "Financial"; break;
case FDCat_Inf: pStr = "Information"; break;
case FDCat_Math: pStr = "Mathematical"; break;
case FDCat_Tech: pStr = "Technical"; break;
default:
pStr = pDefCatName; break;
}
aRet = STRFROMASCII( pStr );
}
else
aRet = STRFROMASCII( pDefCatName );
return aRet;
}
STRING SAL_CALL AnalysisAddIn::getDisplayCategoryName( const STRING& aProgrammaticFunctionName ) THROWDEF_RTE
{
// return translated strings, not used for predefined categories
// return STRFROMASCII( "Add-In" );
const FuncData* p = pFD->Get( aProgrammaticFunctionName );
STRING aRet;
if( p )
{
const sal_Char* pStr;
switch( p->GetCategory() )
{
case FDCat_DateTime: pStr = "Date&Time"; break;
case FDCat_Finance: pStr = "Financial"; break;
case FDCat_Inf: pStr = "Information"; break;
case FDCat_Math: pStr = "Mathematical"; break;
case FDCat_Tech: pStr = "Technical"; break;
default:
pStr = pDefCatName; break;
}
aRet = STRFROMASCII( pStr );
}
else
aRet = STRFROMASCII( pDefCatName );
return aRet;
}
static const sal_Char* pLang[] = { "de", "en" };
static const sal_Char* pCoun[] = { "DE", "US" };
static const sal_uInt32 nNumOfLoc = SAL_N_ELEMENTS(pLang);
void AnalysisAddIn::InitDefLocales( void )
{
pDefLocales = new CSS::lang::Locale[ nNumOfLoc ];
for( sal_uInt32 n = 0 ; n < nNumOfLoc ; n++ )
{
pDefLocales[ n ].Language = STRING::createFromAscii( pLang[ n ] );
pDefLocales[ n ].Country = STRING::createFromAscii( pCoun[ n ] );
}
}
inline const CSS::lang::Locale& AnalysisAddIn::GetLocale( sal_uInt32 nInd )
{
if( !pDefLocales )
InitDefLocales();
if( nInd < sizeof( pLang ) )
return pDefLocales[ nInd ];
else
return aFuncLoc;
}
SEQofLocName SAL_CALL AnalysisAddIn::getCompatibilityNames( const STRING& aProgrammaticName ) THROWDEF_RTE
{
const FuncData* p = pFD->Get( aProgrammaticName );
if( !p )
return SEQofLocName( 0 );
const StringList& r = p->GetCompNameList();
sal_uInt32 nCount = r.Count();
SEQofLocName aRet( nCount );
CSS::sheet::LocalizedName* pArray = aRet.getArray();
for( sal_uInt32 n = 0 ; n < nCount ; n++ )
{
pArray[ n ] = CSS::sheet::LocalizedName( GetLocale( n ), *r.Get( n ) );
}
return aRet;
}
// XAnalysis
/**
* Workday
*/
sal_Int32 SAL_CALL AnalysisAddIn::getWorkday( constREFXPS& xOptions,
sal_Int32 nDate, sal_Int32 nDays, const ANY& aHDay ) THROWDEF_RTE_IAE
{
if( !nDays )
return nDate;
sal_Int32 nNullDate = GetNullDate( xOptions );
SortedIndividualInt32List aSrtLst;
aSrtLst.InsertHolidayList( aAnyConv, xOptions, aHDay, nNullDate, sal_False );
sal_Int32 nActDate = nDate + nNullDate;
if( nDays > 0 )
{
if( GetDayOfWeek( nActDate ) == 5 )
// when starting on Saturday, assuming we're starting on Sunday to get the jump over the weekend
nActDate++;
while( nDays )
{
nActDate++;
if( GetDayOfWeek( nActDate ) < 5 )
{
if( !aSrtLst.Find( nActDate ) )
nDays--;
}
else
nActDate++; // jump over weekend
}
}
else
{
if( GetDayOfWeek( nActDate ) == 6 )
// when starting on Sunday, assuming we're starting on Saturday to get the jump over the weekend
nActDate--;
while( nDays )
{
nActDate--;
if( GetDayOfWeek( nActDate ) < 5 )
{
if( !aSrtLst.Find( nActDate ) )
nDays++;
}
else
nActDate--; // jump over weekend
}
}
return nActDate - nNullDate;
}
/**
* Yearfrac
*/
double SAL_CALL AnalysisAddIn::getYearfrac( constREFXPS& xOpt,
sal_Int32 nStartDate, sal_Int32 nEndDate, const ANY& rMode ) THROWDEF_RTE_IAE
{
double fRet = GetYearFrac( xOpt, nStartDate, nEndDate, getDateMode( xOpt, rMode ) );
RETURN_FINITE( fRet );
}
sal_Int32 SAL_CALL AnalysisAddIn::getEdate( constREFXPS& xOpt, sal_Int32 nStartDate, sal_Int32 nMonths ) THROWDEF_RTE_IAE
{
sal_Int32 nNullDate = GetNullDate( xOpt );
ScaDate aDate( nNullDate, nStartDate, 5 );
aDate.addMonths( nMonths );
return aDate.getDate( nNullDate );
}
sal_Int32 SAL_CALL AnalysisAddIn::getWeeknum( constREFXPS& xOpt, sal_Int32 nDate, sal_Int32 nMode ) THROWDEF_RTE_IAE
{
nDate += GetNullDate( xOpt );
sal_uInt16 nDay, nMonth, nYear;
DaysToDate( nDate, nDay, nMonth, nYear );
sal_Int32 nFirstInYear = DateToDays( 1, 1, nYear );
sal_uInt16 nFirstDayInYear = GetDayOfWeek( nFirstInYear );
return ( nDate - nFirstInYear + ( ( nMode == 1 )? ( nFirstDayInYear + 1 ) % 7 : nFirstDayInYear ) ) / 7 + 1;
}
sal_Int32 SAL_CALL AnalysisAddIn::getEomonth( constREFXPS& xOpt, sal_Int32 nDate, sal_Int32 nMonths ) THROWDEF_RTE_IAE
{
sal_Int32 nNullDate = GetNullDate( xOpt );
nDate += nNullDate;
sal_uInt16 nDay, nMonth, nYear;
DaysToDate( nDate, nDay, nMonth, nYear );
sal_Int32 nNewMonth = nMonth + nMonths;
if( nNewMonth > 12 )
{
nYear = sal::static_int_cast<sal_uInt16>( nYear + ( nNewMonth / 12 ) );
nNewMonth %= 12;
}
else if( nNewMonth < 1 )
{
nNewMonth = -nNewMonth;
nYear = sal::static_int_cast<sal_uInt16>( nYear - ( nNewMonth / 12 ) );
nYear--;
nNewMonth %= 12;
nNewMonth = 12 - nNewMonth;
}
return DateToDays( DaysInMonth( sal_uInt16( nNewMonth ), nYear ), sal_uInt16( nNewMonth ), nYear ) - nNullDate;
}
sal_Int32 SAL_CALL AnalysisAddIn::getNetworkdays( constREFXPS& xOpt,
sal_Int32 nStartDate, sal_Int32 nEndDate, const ANY& aHDay ) THROWDEF_RTE_IAE
{
sal_Int32 nNullDate = GetNullDate( xOpt );
SortedIndividualInt32List aSrtLst;
aSrtLst.InsertHolidayList( aAnyConv, xOpt, aHDay, nNullDate, sal_False );
sal_Int32 nActDate = nStartDate + nNullDate;
sal_Int32 nStopDate = nEndDate + nNullDate;
sal_Int32 nCnt = 0;
if( nActDate <= nStopDate )
{
while( nActDate <= nStopDate )
{
if( GetDayOfWeek( nActDate ) < 5 && !aSrtLst.Find( nActDate ) )
nCnt++;
nActDate++;
}
}
else
{
while( nActDate >= nStopDate )
{
if( GetDayOfWeek( nActDate ) < 5 && !aSrtLst.Find( nActDate ) )
nCnt--;
nActDate--;
}
}
return nCnt;
}
sal_Int32 SAL_CALL AnalysisAddIn::getIseven( sal_Int32 nVal ) THROWDEF_RTE_IAE
{
return ( nVal & 0x00000001 )? 0 : 1;
}
sal_Int32 SAL_CALL AnalysisAddIn::getIsodd( sal_Int32 nVal ) THROWDEF_RTE_IAE
{
return ( nVal & 0x00000001 )? 1 : 0;
}
double SAL_CALL
AnalysisAddIn::getMultinomial( constREFXPS& xOpt, const SEQSEQ( sal_Int32 )& aVLst,
const SEQ( uno::Any )& aOptVLst ) THROWDEF_RTE_IAE
{
ScaDoubleListGE0 aValList;
aValList.Append( aVLst );
aValList.Append( aAnyConv, xOpt, aOptVLst );
if( aValList.Count() == 0 )
return 0.0;
sal_Int32 nZ = 0;
double fN = 1.0;
for( const double *p = aValList.First(); p; p = aValList.Next() )
{
double fInt = (*p >= 0.0) ? rtl::math::approxFloor( *p ) : rtl::math::approxCeil( *p );
if ( fInt < 0.0 || fInt > 170.0 )
THROW_IAE;
sal_Int32 n = static_cast< sal_Int32 >( fInt );
if( n > 0 )
{
nZ += n;
fN *= Fak( n );
}
}
if( nZ > 170 )
THROW_IAE;
double fRet = Fak( nZ ) / fN;
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getSeriessum( double fX, double fN, double fM, const SEQSEQ( double )& aCoeffList ) THROWDEF_RTE_IAE
{
double fRet = 0.0;
// #i32269# 0^0 is undefined, Excel returns #NUM! error
if( fX == 0.0 && fN == 0 )
THROW_RTE;
if( fX != 0.0 )
{
sal_Int32 n1, n2;
sal_Int32 nE1 = aCoeffList.getLength();
sal_Int32 nE2;
for( n1 = 0 ; n1 < nE1 ; n1++ )
{
const SEQ( double )& rList = aCoeffList[ n1 ];
nE2 = rList.getLength();
const double* pList = rList.getConstArray();
for( n2 = 0 ; n2 < nE2 ; n2++ )
{
fRet += pList[ n2 ] * pow( fX, fN );
fN += fM;
}
}
}
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getQuotient( double fNum, double fDenom ) THROWDEF_RTE_IAE
{
double fRet;
if( (fNum < 0) != (fDenom < 0) )
fRet = ::rtl::math::approxCeil( fNum / fDenom );
else
fRet = ::rtl::math::approxFloor( fNum / fDenom );
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getMround( double fNum, double fMult ) THROWDEF_RTE_IAE
{
if( fMult == 0.0 )
return fMult;
double fRet = fMult * ::rtl::math::round( fNum / fMult );
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getSqrtpi( double fNum ) THROWDEF_RTE_IAE
{
double fRet = sqrt( fNum * PI );
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getRandbetween( double fMin, double fMax ) THROWDEF_RTE_IAE
{
fMin = ::rtl::math::round( fMin, 0, rtl_math_RoundingMode_Up );
fMax = ::rtl::math::round( fMax, 0, rtl_math_RoundingMode_Up );
if( fMin > fMax )
THROW_IAE;
// fMax -> range
double fRet = fMax - fMin + 1.0;
fRet *= rand();
fRet /= (RAND_MAX + 1.0);
fRet += fMin;
fRet = floor( fRet ); // simple floor is sufficient here
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getGcd( constREFXPS& xOpt, const SEQSEQ( double )& aVLst, const SEQ( uno::Any )& aOptVLst ) THROWDEF_RTE_IAE
{
ScaDoubleListGT0 aValList;
aValList.Append( aVLst );
aValList.Append( aAnyConv, xOpt, aOptVLst );
if( aValList.Count() == 0 )
return 0.0;
const double* p = aValList.First();
double f = *p;
p = aValList.Next();
while( p )
{
f = GetGcd( *p, f );
p = aValList.Next();
}
RETURN_FINITE( f );
}
double SAL_CALL AnalysisAddIn::getLcm( constREFXPS& xOpt, const SEQSEQ( double )& aVLst, const SEQ( uno::Any )& aOptVLst ) THROWDEF_RTE_IAE
{
ScaDoubleListGE0 aValList;
aValList.Append( aVLst );
aValList.Append( aAnyConv, xOpt, aOptVLst );
if( aValList.Count() == 0 )
return 0.0;
const double* p = aValList.First();
double f = *p;
if( f == 0.0 )
return f;
p = aValList.Next();
while( p )
{
double fTmp = *p;
if( f == 0.0 )
return f;
else
f = fTmp * f / GetGcd( fTmp, f );
p = aValList.Next();
}
RETURN_FINITE( f );
}
double SAL_CALL AnalysisAddIn::getBesseli( double fNum, sal_Int32 nOrder ) THROWDEF_RTE_IAE_NCE
{
double fRet = sca::analysis::BesselI( fNum, nOrder );
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getBesselj( double fNum, sal_Int32 nOrder ) THROWDEF_RTE_IAE_NCE
{
double fRet = sca::analysis::BesselJ( fNum, nOrder );
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getBesselk( double fNum, sal_Int32 nOrder ) THROWDEF_RTE_IAE_NCE
{
if( nOrder < 0 || fNum <= 0.0 )
THROW_IAE;
double fRet = sca::analysis::BesselK( fNum, nOrder );
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getBessely( double fNum, sal_Int32 nOrder ) THROWDEF_RTE_IAE_NCE
{
if( nOrder < 0 || fNum <= 0.0 )
THROW_IAE;
double fRet = sca::analysis::BesselY( fNum, nOrder );
RETURN_FINITE( fRet );
}
const double SCA_MAX2 = 511.0; // min. val for binary numbers (9 bits + sign)
const double SCA_MIN2 = -SCA_MAX2-1.0; // min. val for binary numbers (9 bits + sign)
const double SCA_MAX8 = 536870911.0; // max. val for octal numbers (29 bits + sign)
const double SCA_MIN8 = -SCA_MAX8-1.0; // min. val for octal numbers (29 bits + sign)
const double SCA_MAX16 = 549755813888.0; // max. val for hexadecimal numbers (39 bits + sign)
const double SCA_MIN16 = -SCA_MAX16-1.0; // min. val for hexadecimal numbers (39 bits + sign)
const sal_Int32 SCA_MAXPLACES = 10; // max. number of places
STRING SAL_CALL AnalysisAddIn::getBin2Oct( constREFXPS& xOpt, const STRING& aNum, const ANY& rPlaces ) THROWDEF_RTE_IAE
{
double fVal = ConvertToDec( aNum, 2, SCA_MAXPLACES );
sal_Int32 nPlaces = 0;
sal_Bool bUsePlaces = aAnyConv.getInt32( nPlaces, xOpt, rPlaces );
return ConvertFromDec( fVal, SCA_MIN8, SCA_MAX8, 8, nPlaces, SCA_MAXPLACES, bUsePlaces );
}
double SAL_CALL AnalysisAddIn::getBin2Dec( const STRING& aNum ) THROWDEF_RTE_IAE
{
double fRet = ConvertToDec( aNum, 2, SCA_MAXPLACES );
RETURN_FINITE( fRet );
}
STRING SAL_CALL AnalysisAddIn::getBin2Hex( constREFXPS& xOpt, const STRING& aNum, const ANY& rPlaces ) THROWDEF_RTE_IAE
{
double fVal = ConvertToDec( aNum, 2, SCA_MAXPLACES );
sal_Int32 nPlaces = 0;
sal_Bool bUsePlaces = aAnyConv.getInt32( nPlaces, xOpt, rPlaces );
return ConvertFromDec( fVal, SCA_MIN16, SCA_MAX16, 16, nPlaces, SCA_MAXPLACES, bUsePlaces );
}
STRING SAL_CALL AnalysisAddIn::getOct2Bin( constREFXPS& xOpt, const STRING& aNum, const ANY& rPlaces ) THROWDEF_RTE_IAE
{
double fVal = ConvertToDec( aNum, 8, SCA_MAXPLACES );
sal_Int32 nPlaces = 0;
sal_Bool bUsePlaces = aAnyConv.getInt32( nPlaces, xOpt, rPlaces );
return ConvertFromDec( fVal, SCA_MIN2, SCA_MAX2, 2, nPlaces, SCA_MAXPLACES, bUsePlaces );
}
double SAL_CALL AnalysisAddIn::getOct2Dec( const STRING& aNum ) THROWDEF_RTE_IAE
{
double fRet = ConvertToDec( aNum, 8, SCA_MAXPLACES );
RETURN_FINITE( fRet );
}
STRING SAL_CALL AnalysisAddIn::getOct2Hex( constREFXPS& xOpt, const STRING& aNum, const ANY& rPlaces ) THROWDEF_RTE_IAE
{
double fVal = ConvertToDec( aNum, 8, SCA_MAXPLACES );
sal_Int32 nPlaces = 0;
sal_Bool bUsePlaces = aAnyConv.getInt32( nPlaces, xOpt, rPlaces );
return ConvertFromDec( fVal, SCA_MIN16, SCA_MAX16, 16, nPlaces, SCA_MAXPLACES, bUsePlaces );
}
STRING SAL_CALL AnalysisAddIn::getDec2Bin( constREFXPS& xOpt, sal_Int32 nNum, const ANY& rPlaces ) THROWDEF_RTE_IAE
{
sal_Int32 nPlaces = 0;
sal_Bool bUsePlaces = aAnyConv.getInt32( nPlaces, xOpt, rPlaces );
return ConvertFromDec( nNum, SCA_MIN2, SCA_MAX2, 2, nPlaces, SCA_MAXPLACES, bUsePlaces );
}
STRING SAL_CALL AnalysisAddIn::getDec2Oct( constREFXPS& xOpt, sal_Int32 nNum, const ANY& rPlaces ) THROWDEF_RTE_IAE
{
sal_Int32 nPlaces = 0;
sal_Bool bUsePlaces = aAnyConv.getInt32( nPlaces, xOpt, rPlaces );
return ConvertFromDec( nNum, SCA_MIN8, SCA_MAX8, 8, nPlaces, SCA_MAXPLACES, bUsePlaces );
}
STRING SAL_CALL AnalysisAddIn::getDec2Hex( constREFXPS& xOpt, double fNum, const ANY& rPlaces ) THROWDEF_RTE_IAE
{
sal_Int32 nPlaces = 0;
sal_Bool bUsePlaces = aAnyConv.getInt32( nPlaces, xOpt, rPlaces );
return ConvertFromDec( fNum, SCA_MIN16, SCA_MAX16, 16, nPlaces, SCA_MAXPLACES, bUsePlaces );
}
STRING SAL_CALL AnalysisAddIn::getHex2Bin( constREFXPS& xOpt, const STRING& aNum, const ANY& rPlaces ) THROWDEF_RTE_IAE
{
double fVal = ConvertToDec( aNum, 16, SCA_MAXPLACES );
sal_Int32 nPlaces = 0;
sal_Bool bUsePlaces = aAnyConv.getInt32( nPlaces, xOpt, rPlaces );
return ConvertFromDec( fVal, SCA_MIN2, SCA_MAX2, 2, nPlaces, SCA_MAXPLACES, bUsePlaces );
}
double SAL_CALL AnalysisAddIn::getHex2Dec( const STRING& aNum ) THROWDEF_RTE_IAE
{
double fRet = ConvertToDec( aNum, 16, SCA_MAXPLACES );
RETURN_FINITE( fRet );
}
STRING SAL_CALL AnalysisAddIn::getHex2Oct( constREFXPS& xOpt, const STRING& aNum, const ANY& rPlaces ) THROWDEF_RTE_IAE
{
double fVal = ConvertToDec( aNum, 16, SCA_MAXPLACES );
sal_Int32 nPlaces = 0;
sal_Bool bUsePlaces = aAnyConv.getInt32( nPlaces, xOpt, rPlaces );
return ConvertFromDec( fVal, SCA_MIN8, SCA_MAX8, 8, nPlaces, SCA_MAXPLACES, bUsePlaces );
}
sal_Int32 SAL_CALL AnalysisAddIn::getDelta( constREFXPS& xOpt, double fNum1, const ANY& rNum2 ) THROWDEF_RTE_IAE
{
return fNum1 == aAnyConv.getDouble( xOpt, rNum2, 0.0 );
}
double SAL_CALL AnalysisAddIn::getErf( constREFXPS& xOpt, double fLL, const ANY& rUL ) THROWDEF_RTE_IAE
{
double fUL, fRet;
sal_Bool bContainsValue = aAnyConv.getDouble( fUL, xOpt, rUL );
fRet = bContainsValue ? (Erf( fUL ) - Erf( fLL )) : Erf( fLL );
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getErfc( double f ) THROWDEF_RTE_IAE
{
double fRet = Erfc( f );
RETURN_FINITE( fRet );
}
sal_Int32 SAL_CALL AnalysisAddIn::getGestep( constREFXPS& xOpt, double fNum, const ANY& rStep ) THROWDEF_RTE_IAE
{
return fNum >= aAnyConv.getDouble( xOpt, rStep, 0.0 );
}
double SAL_CALL AnalysisAddIn::getFactdouble( sal_Int32 nNum ) THROWDEF_RTE_IAE
{
double fRet = FactDouble( nNum );
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getImabs( const STRING& aNum ) THROWDEF_RTE_IAE
{
double fRet = Complex( aNum ).Abs();
RETURN_FINITE( fRet );
}
double SAL_CALL AnalysisAddIn::getImaginary( const STRING& aNum ) THROWDEF_RTE_IAE
{
double fRet = Complex( aNum ).Imag();
RETURN_FINITE( fRet );
}
STRING SAL_CALL AnalysisAddIn::getImpower( const STRING& aNum, double f ) THROWDEF_RTE_IAE
{
Complex z( aNum );
z.Power( f );
return z.GetString();
}
double SAL_CALL AnalysisAddIn::getImargument( const STRING& aNum ) THROWDEF_RTE_IAE
{
double fRet = Complex( aNum ).Arg();
RETURN_FINITE( fRet );
}
STRING SAL_CALL AnalysisAddIn::getImcos( const STRING& aNum ) THROWDEF_RTE_IAE
{
Complex z( aNum );
z.Cos();
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getImdiv( const STRING& aDivid, const STRING& aDivis ) THROWDEF_RTE_IAE
{
Complex z( aDivid );
z.Div( Complex( aDivis ) );
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getImexp( const STRING& aNum ) THROWDEF_RTE_IAE
{
Complex z( aNum );
z.Exp();
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getImconjugate( const STRING& aNum ) THROWDEF_RTE_IAE
{
Complex z( aNum );
z.Conjugate();
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getImln( const STRING& aNum ) THROWDEF_RTE_IAE
{
Complex z( aNum );
z.Ln();
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getImlog10( const STRING& aNum ) THROWDEF_RTE_IAE
{
Complex z( aNum );
z.Log10();
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getImlog2( const STRING& aNum ) THROWDEF_RTE_IAE
{
Complex z( aNum );
z.Log2();
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getImproduct( constREFXPS&, const SEQSEQ( STRING )& aNum1, const SEQ( uno::Any )& aNL ) THROWDEF_RTE_IAE
{
ComplexList z_list;
z_list.Append( aNum1, AH_IgnoreEmpty );
z_list.Append( aNL, AH_IgnoreEmpty );
const Complex* p = z_list.First();
if( !p )
return Complex( 0 ).GetString();
Complex z( *p );
for( p = z_list.Next() ; p ; p = z_list.Next() )
z.Mult( *p );
return z.GetString();
}
double SAL_CALL AnalysisAddIn::getImreal( const STRING& aNum ) THROWDEF_RTE_IAE
{
double fRet = Complex( aNum ).Real();
RETURN_FINITE( fRet );
}
STRING SAL_CALL AnalysisAddIn::getImsin( const STRING& aNum ) THROWDEF_RTE_IAE
{
Complex z( aNum );
z.Sin();
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getImsub( const STRING& aNum1, const STRING& aNum2 ) THROWDEF_RTE_IAE
{
Complex z( aNum1 );
z.Sub( Complex( aNum2 ) );
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getImsum( constREFXPS&, const SEQSEQ( STRING )& aNum1, const SEQ( CSS::uno::Any )& aFollowingPars ) THROWDEF_RTE_IAE
{
ComplexList z_list;
z_list.Append( aNum1, AH_IgnoreEmpty );
z_list.Append( aFollowingPars, AH_IgnoreEmpty );
const Complex* p = z_list.First();
if( !p )
return Complex( 0 ).GetString();
Complex z( *p );
for( p = z_list.Next() ; p ; p = z_list.Next() )
z.Add( *p );
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getImsqrt( const STRING& aNum ) THROWDEF_RTE_IAE
{
Complex z( aNum );
z.Sqrt();
return z.GetString();
}
STRING SAL_CALL AnalysisAddIn::getComplex( double fR, double fI, const ANY& rSuff ) THROWDEF_RTE_IAE
{
sal_Bool bi;
switch( rSuff.getValueTypeClass() )
{
case uno::TypeClass_VOID:
bi = sal_True;
break;
case uno::TypeClass_STRING:
{
const STRING* pSuff = ( const STRING* ) rSuff.getValue();
bi = pSuff->compareToAscii( "i" ) == 0 || pSuff->getLength() == 0;
if( !bi && pSuff->compareToAscii( "j" ) != 0 )
THROW_IAE;
}
break;
default:
THROW_IAE;
}
return Complex( fR, fI, bi ? 'i' : 'j' ).GetString();
}
double SAL_CALL AnalysisAddIn::getConvert( double f, const STRING& aFU, const STRING& aTU ) THROWDEF_RTE_IAE
{
if( !pCDL )
pCDL = new ConvertDataList();
double fRet = pCDL->Convert( f, aFU, aTU );
RETURN_FINITE( fRet );
}
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